288 lines
5.9 KiB
C
288 lines
5.9 KiB
C
/* $Header$ */
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/*
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* (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands.
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* See the copyright notice in the ACK home directory, in the file "Copyright".
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*/
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#include <stdio.h>
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#include <em_spec.h>
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#include <em_mnem.h>
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#include "types.h"
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#include "debug.h"
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#include "alloc.h"
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#include "global.h"
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#include "lset.h"
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#include "aux.h"
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struct class {
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byte src_class;
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byte res_class;
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};
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typedef struct class *class_p;
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#define NOCLASS 0
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#define CLASS1 1
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#define CLASS2 2
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#define CLASS3 3
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#define CLASS4 4
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#define CLASS5 5
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#define CLASS6 6
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#define CLASS7 7
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#define CLASS8 8
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#define CLASS9 9
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#define CLASS10 10
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#define CLASS11 11
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#define CLASS12 12
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#include "classdefs.h"
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/* The file classdefs.h contains the table classtab. It is
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* generated automatically from the file classdefs.src.
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*/
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STATIC bool classes(instr,src_out,res_out)
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int instr;
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int *src_out, *res_out;
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{
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/* Determine the classes of the given instruction */
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class_p c;
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if (instr < sp_fmnem || instr > sp_lmnem) return FALSE;
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c = &classtab[instr];
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if (c->src_class == NOCLASS) return FALSE;
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*src_out = c->src_class;
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*res_out = c->res_class;
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return TRUE;
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}
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STATIC bool uses_arg(class)
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int class;
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{
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/* See if a member of the given class uses
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* an argument.
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*/
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switch(class) {
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case CLASS1:
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case CLASS2:
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case CLASS3:
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case CLASS4:
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case CLASS11:
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case CLASS12:
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return TRUE;
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default:
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return FALSE;
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}
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/* NOTREACHED */
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}
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STATIC bool uses_2args(class)
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int class;
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{
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/* See if a member of the given class uses
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* 2 arguments.
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*/
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return class == CLASS10;
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}
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STATIC bool parse_locs(l,c1_out,c2_out)
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line_p l;
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offset *c1_out, *c2_out;
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{
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if (INSTR(l) == op_loc && INSTR(PREV(l)) == op_loc) {
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*c1_out = off_set(l);
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*c2_out = off_set(PREV(l));
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return TRUE;
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}
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return FALSE;
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}
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STATIC bool check_args(l,src_class,res_class,arg1_out,arg2_out)
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line_p l;
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int src_class,res_class;
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offset *arg1_out, *arg2_out;
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{
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/* Several EM instructions have an argument
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* giving the size of the operand(s) of
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* the instruction. E.g. a 'adi 4' is a 4-byte
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* addition. The size may also be put on the
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* stack. In this case we give up our
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* efforts to recognize the parameter expression.
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* Some instructions (e.g. CIU) use 2 arguments
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* that are both on the stack. In this case we
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* check if both arguments are LOCs (the usual case),
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* else we give up.
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*/
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if (uses_2args(src_class) || uses_2args(res_class)) {
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return parse_locs(PREV(l),arg1_out,arg2_out);
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}
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if (uses_arg(src_class) || uses_arg(res_class)) {
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if (TYPE(l) == OPSHORT) {
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*arg1_out = (offset) SHORT(l);
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return TRUE;
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} else {
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if (TYPE(l) == OPOFFSET) {
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*arg1_out = OFFSET(l);
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} else {
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return FALSE;
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}
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}
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}
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return TRUE; /* no argument needed */
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}
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STATIC offset nrbytes(class,arg1,arg2)
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int class;
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offset arg1,arg2;
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{
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/* Determine the number of bytes of the given
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* arguments and class.
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*/
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offset n;
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switch(class) {
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case CLASS1:
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n = arg1;
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break;
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case CLASS2:
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n = 2 * arg1;
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break;
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case CLASS3:
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n = arg1 + ws;
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break;
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case CLASS4:
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n = arg1 + ps;
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break;
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case CLASS5:
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n = ws;
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break;
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case CLASS6:
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n = 2 * ws;
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break;
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case CLASS7:
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n = ps;
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break;
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case CLASS8:
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n = 2 * ps;
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break;
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case CLASS9:
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n = 0;
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break;
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case CLASS10:
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n = arg2 + 2*ws;
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break;
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case CLASS11:
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n = arg1 + 2*ps;
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break;
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case CLASS12:
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n = (arg1 < ws ? ws : arg1);
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break;
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default:
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assert(FALSE);
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}
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return n;
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}
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STATIC attrib(l,expect_out,srcb_out,resb_out)
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line_p l;
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offset *expect_out, *srcb_out, *resb_out;
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{
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/* Determine a number of attributes of an EM
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* instruction appearing in an expression.
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* If it is something we don't
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* expect in such expression (e.g. a store)
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* expect_out is set to FALSE. Else we
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* determine the number of bytes popped from
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* the stack by the instruction and the
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* number of bytes pushed on the stack as
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* result.
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*/
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int src_class,res_class;
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offset arg1, arg2;
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if (l == (line_p) 0 || !classes(INSTR(l),&src_class,&res_class) ||
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!check_args(l,src_class,res_class,&arg1,&arg2)) {
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*expect_out = FALSE;
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} else {
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*expect_out = TRUE;
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*srcb_out = nrbytes(src_class,arg1,arg2);
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*resb_out = nrbytes(res_class,arg1,arg2);
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}
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}
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bool parse(l,nbytes,l_out,level,action0)
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line_p l, *l_out;
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offset nbytes;
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int level;
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int (*action0) ();
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{
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/* This is a recursive descent parser for
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* EM expressions.
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* It tries to recognize EM code that loads exactly
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* 'nbytes' bytes on the stack.
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* 'l' is the last instruction of this code.
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* As EM is essentially postfix, this instruction
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* can be regarded as the root node of an expression
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* tree. The EM code is traversed from right to left,
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* i.e. top down. On success, TRUE is returned and
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* 'l_out' will point to the first instruction
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* of the recognized code. On toplevel, when an
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* expression has been recognized, the procedure-parameter
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* 'action0' is called, with parameters: the first and
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* last instruction of the expression and the number of
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* bytes recognized.
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*/
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offset more, expected, sourcebytes,resultbytes;
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line_p lnp;
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more = nbytes; /* #bytes to be recognized */
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while (more > 0) {
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attrib(l,&expected,&sourcebytes,&resultbytes);
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/* Get the attributes of EM instruction 'l'.
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* 'expected' denotes if it is something we can use;
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* 'sourcebytes' and 'resultbytes' are the number of
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* bytes popped resp. pushed by the instruction
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* (e.g. 'adi 2' pops 4 bytes and pushes 2 bytes).
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*/
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if (!expected || (more -= resultbytes) < 0) return FALSE;
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if (sourcebytes == 0) {
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/* a leaf of the expression tree */
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lnp = l;
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} else {
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if (!parse(PREV(l),sourcebytes,&lnp,level+1,action0)) {
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return FALSE;
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}
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}
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if (level == 0) {
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/* at toplevel */
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(*action0) (lnp,l,resultbytes);
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}
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l = PREV(lnp);
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}
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/* Now we've recognized a number of expressions that
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* together push nbytes on the stack.
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*/
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*l_out = lnp;
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return TRUE;
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}
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